Spinal Cord Tracts PDF

Summary

This document details the spinal cord tracts, including ascending and descending tracts. It describes their origins, terminations, and functions. The material is suitable for undergraduate-level studies in neuroanatomy and physiology.

Full Transcript

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Spinal cord

1. The CNS is composed of the brain and
spinal cord

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Spinal cord

1. The CNS is composed of the brain and
spinal cord

Brain

Gray
matter

White
matter
Spinal
cord

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Introduction: Spinal Cord Tracts
The white matter is composed of
ascending and descending fiber tracts.

Ascending tracts carry sensory impulses
and are given the prefix spino- with a suffix
that indicates the brain region it synapses
on; example: lateral spinothalamic tract

Descending tracts carry motor impulses and
are given the suffix -spinal, and the prefix
indicates the brain region they come from;
example: anterior corticospinal tract

el bialy, Safaa & Weng, Robin & Jalali, Alireza. (2019). Development of a 3D Printed Neuroanatomy Teaching Model. University of Ottawa Journal of Medicine. 9. 49-53. 10.18192/uojm.v9i1.4057.

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 Ascending Tracts: anterolateral 4

spinothalamic
Principal Ascending Tracts of the Spinal Cord
Tract Origin Termination Function
Anterolateral Posterior horn on one side Thalamus, then cerebral Conducts pain and temperature
spinothalamic of cord but crosses to cortex impulses that are interpreted
opposite side within cerebral cortex

Dorsal horn
spinal cord

Dorsal horn
spinal cord

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 Ascending Tracts: anterolateral 5

spinothalamic

Third order Neuron
cell body

First order Neuron
cell body
Second order
Neuron cell body

First order Neuron
Second order cell body
Neuron cell body

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 Ascending Tracts: dorsal columns 6

medial lemniscus
Principal Ascending Tracts of the Spinal Cord

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 Ascending Tracts: dorsal column 7

medial lemniscus

Third order Neuron
cell body

First order Neuron
cell body
Second order
Neuron cell body

First order Neuron
Second order cell body
Neuron cell body

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Descending Tracts
1.The descending tracts are the pathways by
which motor signals are sent from upper motor
neurons to lower motor neurons. The lower
motor neurons then directly innervate muscles
to produce movement.
2.Two major groups:.
a.Pyramidal: originate from the cerebral
cortex to the spinal cord and brain stem.
They are responsible for the voluntary control
of the musculature of the body and face.
b.Extrapyramidal tracts: originate in the brain
stem. They are responsible for
1)The involuntary and automatic control of
all musculature, such as muscle tone,
balance, posture and locomotion.
2)Refine and adjust movements initiated
by the pyramidal tracts to ensure
smooth execution.

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Pyramidal Tracts
1. Two major groups:
a. Corticospinal: supplies the musculature of the body.
b. Corticobulbar supplies the musculature of head and neck.

Corticospinal Corticobulbar

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Pyramidal Tracts: corticospinal
Tract Category Origin Crossed/Uncrossed
Lateral corticospinal Pyramidal Cerebral cortex Crossed
Anterior corticospinal Pyramidal Cerebral cortex Uncrossed/Crossed

Cell bodies of the upper motor neurons are located in the
precentral gyrus (Primary motor cortex).
80 to 90% cross in the medulla pyramids and
descend as lateral corticospinal tracts.
Those that do not cross in the medulla, descend as
anterior corticospinal tracts and cross in the spinal
cord at the level that the nerves leave the cord.
Those that do cross in the medulla, descend as lateral
corticospinal tracts.

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Extrapyramidal Tracts
Tract Category Origin Crossed/Uncrossed
Rubrospinal Extrapyramidal Red nucleus (midbrain) Crossed
Tectospinal Extrapyramidal Superior colliculus (midbrain) Crossed
Vestibulospinal Extrapyramidal Vestibular nuclei (medulla oblongata) Uncrossed
Reticulospinal Extrapyramidal Reticular formation (medulla and pons) Crossed

The extrapyramidal tracts originate in the
brainstem, carrying motor fibers to the spinal
cord. They are responsible for the
involuntary and automatic control of all
musculature.
Reticulospinal tracts are the major
descending extrapyramidal tracts.
Vestibulospinal tracts arise from the
vestibular nuclei in the medulla
oblongata
Rubrospinal tracts arise from the red
nuclei.
Tectospinal tracts arise from the
tectum in the midbrain.
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I. The Peripheral Nervous System

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 Peripheral Nervous System (PNS): 1
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introduction
Composed of:
1. Nerves: bundles of axons in the PNS
are referred to as nerves. These
structures in the periphery are different
than the central counterpart, called a
tract.
1. Cranial Nerves
2. Spinal Nerves

2. Ganglia: group of neuron cell bodies in
the periphery. They can be categorized,
for the most part, as either sensory
ganglia or autonomic ganglia, referring
to their primary functions.

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Cranial Nerves
1. Nerves that arise directly from nuclei in the brain
2. Twelve pairs
3. Most are mixed nerves with both sensory and motor fibers (i.e. the vagus nerve [cranial nerve X] )
4. Those associated with vision, olfaction, and hearing are sensory only. https://co.pinterest.com/pin/55943220356399163/?lp=true

Cranial Nerves

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Spinal Nerves
1. Nerves that arise directly from the spinal cord
2. 31 pairs: 8 cervical, 12 thoracic, 5 lumbar, 5 sacral, 1
coccygeal
3. Spinal Nerves are mixed nerve.
4. The sensory fibers enter the cord via the
posterior/dorsal root, and the motor fibers exit by
way of the anterior/ventral root

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 Peripheral Nervous System (PNS): 1
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introduction
Composed of:
1. Nerves: bundles of axons in the PNS
are referred to as nerves. These
structures in the periphery are different
than the central counterpart, called a
tract.
1. Cranial Nerves
2. Spinal Nerves

2. Ganglia: group of neuron cell bodies in
the periphery. They can be categorized,
for the most part, as either sensory
ganglia or autonomic ganglia, referring
to their primary functions.

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Ganglia

A ganglia is a group of neuron cell bodies in
the periphery. They work as relay station for
nerve signals. One nerve enters
(preganglionic) and another nerve exits
(postganglionic) from each ganglion.

The cell bodies of the preganglionic
neurons are in the brainstem or spinal cord of
the central nervous system (CNS). The cell
bodies of the postganglionic neurons are in
the ganglia.

Ganglia can be categorized, for the most part,
as either sensory ganglia or autonomic
ganglia, referring to their primary functions.

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Different part of the PNS
1. Somatic nervous system: serves the skin, skeletal muscles, and tendons. It includes
nerves that take sensory information from external sensory receptors to the CNS and
motor commands away from the CNS to the skeletal muscles. Sensory nerve fibers in the
peripheral nerves are the peripheral axonal process of neurons in the dorsal root ganglion.
2. Autonomic nervous system: innervates all effector organs and tissues except for skeletal
muscles. It is autonomic because it functions subconsciously and involuntarily.

Somatic Nervous System

Autonomic Nervous System
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Autonomic Nervous System

Autonomic nervous system regulates:
Activities of glands
Smooth muscle function
Function of heart and circulatory
system
Function of digestive system etc…

Visceral organs innervated by the Autonomic
Nervous system

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Autonomic Nervous System
Sympatetic - fight or flight
Involved in responses that would be associated
with fighting or fleeing, such as increasing
heart rate and blood pressure as well as
constricting blood vessels in the skin and
dilating them in muscles.

The sympathetic division is most active during
times of excitement and physical activity.

Parasympatetic - rest and digest
Involved in energy conservation functions and
increases gastrointestinal motility and secretion.
It also increases bladder contractility.

The parasympathetic division is most active
during rest and stimulates digestive activities.

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Sympathetic Division
1.The axons of preganglionic neurons come
from the thoracic and lumbar regions of the Sympathetic is in red
spinal cord.

2.Preganglionic neurons (not all of them…see
point 3 below) synapse in sympathetic ganglia
that run parallel to the spinal cord.

1. These are called the paravertebral ganglia.

2. Paravertebral ganglia are connected,
forming a sympathetic chain of ganglia.

3.Many of the sympathetic neurons that exit the
spinal cord below the diaphragm do not
synapse in the sympathetic chain of ganglia.

1. Collateral ganglia include celiac, superior
mesenteric, and inferior mesenteric ganglia

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Sympathetic Division: chain of ganglia
It allows nerve fibers to travel to spinal
nerves that are superior and inferior to
the one in which they originated.

Convergence and Divergence
Because preganglionic neurons can branch
and synapse in ganglia at any level, there is:
1) Divergence: One preganglionic neuron
synapses on several postganglionic
neurons at different levels.
2) Convergence: Several preganglionic
neurons at different levels synapse on
one postganglionic neuron.
Allows the sympathetic division to act as
a single unit through mass activation and
to be tonically active

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Parasympathetic Division
Preganglionic neurons come from the
brain (brainstem) and sacral region of
the spinal cord.

a. Also called the craniosacral
division. Some preganglionic
neurons synapse on small terminal
ganglia or intramural ganglia, so
named because they lie near or
within (respectively) the organs
they innervate.

1) Exception are the four
parasympathetic ganglia of
the head and neck.

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 Parasympathetic Division: the vagus 2
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nerve
The vagus nerve (X) represents the main
Vagus Nerve Innervation
component of the parasympathetic
nervous system.
The vagus nerve oversees a vast array of
crucial bodily functions, including
control of mood,
immune response,
digestion,
and heart rate.
It establishes one of the connections
between the brain and the
gastrointestinal tract and sends
information about the state of the inner
organs to the brain via afferent sensory
fibers.

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III. Functions of the Autonomic Nervous
System

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Autonomic Nervous System
Sympatetic - fight or flight
Involved in responses that would be associated
with fighting or fleeing, such as increasing
heart rate and blood pressure as well as
constricting blood vessels in the skin and
dilating them in muscles. The sympathetic
division is most active during times of
excitement and physical activity.

Parasympatetic - rest and digest
Involved in energy conservation functions and
increases gastrointestinal motility and secretion.
It also increases bladder contractility. The
parasympathetic division is most active during
rest and stimulates digestive activities.

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Adrenergic and Cholinergic Synaptic 7

Transmission
1. Cholinergic Synaptic Transmission
a. Acetylcholine (ACh) is the neurotransmitter
used by all preganglionic neurons
(sympathetic and parasympathetic)
a. Always excitatory - nicotinic receptors
b. It is also the neurotransmitter released from
most parasympathetic post ganglionic
neurons.
a. Can be excitatory or inhibitory -
muscarinic receptors.

2. Adrenergic Synaptic Transmission

a. Norepinephrine is the neurotransmitter
released by most sympathetic
postganglionic neurons.
a. Can be excitatory or inhibitory -
noradrenergic alpha or beta receptors.

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Other Autonomic Neurotransmitters
1. Some postganglionic autonomic neurons do not release ACh or
norepinephrine.
a. Called “nonadrenergic, noncholinergic fibers”
b. Proposed neurotransmitters include ATP, vasoactive intestinal
peptide (VIP), and nitric oxide (NO).

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Organs with Dual Innervation
1. Most visceral organs are innervated by both sympathetic and
parasympathetic neurons.
2. The activity of the two divisions of the autonomic system can be:
a. Antagonistic
b. Complementary
c. Cooperative

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Antagonistic action of sympathetic and parasympathetic 0

autonomic system
a. Occur when both divisions produce opposite effects on the
same target
b. Example -
a. Heart rate – sym increases, para decreases
b. Digestive functions – sym decreases, para increases
c. Pupil diameter – sym dilates, para constricts

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Complementary action of sympathetic and 1

parasympathetic autonomic system

a. Occur when both divisions produce similar effects on the
same target
b. Example - Salivary gland secretion: parasympathetic
division stimulates secretion of saliva; sympathetic
constricts blood vessels so the secretion is thicker.

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Cooperative action of sympathetic and parasympathetic 2

autonomic system

a. Occur when both divisions produce different effects that
work together to promote a single action.
b. Example - Urination: parasympathetic division aids in
urinary bladder contraction; sympathetic helps with
bladder muscle tone to promote/control urination reflex
(triggered when the bladder fills with urine).

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Organs Without Dual Innervation
1. The following organs are innervated by the sympathetic
division only:
a. Adrenal medulla
b. Arrector pili muscles in skin
c. Sweat glands in skin
d. Most blood vessels
2. Regulated by increase and decrease in sympathetic nerve
activity
3. Important for body temperature regulation through blood
vessels and sweat glands

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Different part of the PNS
Divided in:

1. Somatic nervous system: sensory and motor nerves that innervate the limbs and body.

2. Autonomic nervous system: innervates all effector organs and tissues except for skeletal muscles. It is autonomic because
it functions subconsciously and involuntarily.

1. Sympathetic

2. Parasympathetic

Somatic Nervous System

Autonomic Nervous System
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Introduction
Ascending tracts and sensory component of cranial nerves are the neural
pathways of sensory systems.

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 Sensory physiology
A sensory system is a part of the nervous system responsible for processing
sensory information. It consists of :

sensory receptors,
neural pathways (slide before),
and parts of the brain involved in sensory perception.

In each sensory modality :

1- a specific type of stimulus energy is
transformed into electrical signals by
specialized receptors.

2- The sensory information is transmitted to the
central nervous system by trains of action
potentials (along the neural pathway) that
represent aspects of the stimulus.

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Receptors

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Introduction to Sensory Receptors
1. Sensory receptors are specialized cells, usually neurons, that detect
and respond to physical and chemical stimuli.
2. Many sensory receptors cells are located at the surface to detect external
stimuli, but others lie within body tissues to monitor internal organ functions
and provide crucial homeostatic feedback regulation

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Introduction to Sensory Receptors
Sensory receptors cells transduce (change) different forms of energy in the
“real world” into nerve impulses.
Different modalities of sensations (sound, light, pressure, taste, odor) arise from
differences in neural pathways and synaptic connections
a. If the optic nerve delivers an impulse, the brain interprets it as light even though
the impulse (in the form of action potential) is the same as for hearing, taste,
olfaction, etc…

Sensory receptors cells Transduction Processing of sensory information
Generation of action potential CNS

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Functional Categories of Sensory
Receptors: Type of Signal

a. According to the type of signal they transduce:
1) Chemoreceptors: sense chemicals in the external (taste, smell) or internal
(CO2) environment
2) Photoreceptors: sense light.
3) Thermoreceptors: respond various degrees of heat.
4) Mechanoreceptors: stimulated by mechanical deformation of the receptor
(touch, hearing).
5) Nociceptors: sense stimuli that accompany tissue damage (high heat, high
pressure acid).

b. According to the type of information they deliver to the brain:
1) Proprioceptors: found in muscles, tendons, and joints. Provide a sense of body
position and allows fine muscle control.
2) Cutaneous (skin) receptors – touch, pressure, heat, cold, and pain
3) Special senses – vision, hearing, taste, smell, equilibrium
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Categories of Sensory Receptors
c. According to the origin of the information:
1) Exteroceptors: respond to stimuli from outside the body; includes
cutaneous receptors and special senses
2) Interoceptors: respond to internal stimuli; found in organs; monitor
blood pressure, pH, and oxygen concentrations.
d. According to how they respond to a stimulus.
1. Phasic receptors
2. Tonic receptors

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Generator (Receptor) Potential
1. Sensory receptors cells behave very similarly to dendrites of neurons.
2. Stimuli produce depolarizations called generator potentials.
a. Similar to EPSPs: It is a graded response
b. Light touch on a Pacinian corpuscle in the skin produces a small
generator potential.
c. Increasing the pressure increases the magnitude of the generator
potential until threshold is met and an action potential occurs.

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Generator (Receptor) Potential

The generator (receptor) potential is (like the EPSP) proportional to the intensity of
the stimulus.
Increased intensity results in increased frequency of action potential after
threshold is reached.

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Generator (Receptor) Potential

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Categories of Sensory Receptors
Tonic
Maintain a high firing rate if the stimulus is applied (they can be no
adapting or slow-adapting).
Examples:
no adapting: pain receptors, and proprioceptors. (A)

slow adapting: Merkel’s discs and Ruffini corpuscles
(touch and pressure), interoceptors. (B)

Phasic: respond with a burst of activity when stimulus is first applied but
quickly adapt to the stimulus by decreasing response (fast-adapting) (C)

a) Allow sensory adaptation – cease to pay attention to constant
stimuli

b) May deliver another burst when stimulus is removed to provide on
and off information

c) Examples - smell, touch (Pacinian Corpuscles), temperature
(actually this can occur with all senses)

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V. The Ears and Hearing

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The sense of Hearing
1. The human ear (and other animals) are sensitive detectors capable of detecting the
fluctuations in air pressure that impinge upon the eardrum.
1) Capable of detecting sound waves with a wide range of frequencies, ranging between
approximately 20 Hz to 20 000 Hz.
2) Cats can detect frequencies as low as approximately 45 Hz and as high as 85 000 Hz.
3) Dolphins can detect frequencies as high as 200 000 Hz.
2. Intensity or loudness, measured in decibels
1) Related to the amplitude of the wave
2) Human optimal range is 0 to 80 dB
3. Frequency or pitch
1) The frequency of sound waves is measured in hertz (Hz), or the number of waves that
pass a fixed point in a second.

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The Ear
1.Outer ear (external ear): Pinna or auricle and external auditory canal – sound
gathering

2.Middle ear: made of tiny bones – modulation of sound vibrations and transfer to the
inner ear.

3.Inner ear: cochlea – transduction of sound vibration into electrical signals.

https://www.britannica.com/science/ear/The-physiology-of-hearing

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The Outer Ear
1.Sound waves enter the outer ear and travel through a narrow passageway called the ear canal
(external auditory meatus), which leads to the eardrum or tympanic membrane.

2.The eardrum vibrates from the incoming sound waves and sends these vibrations to three
tiny bones in the middle ear.

https://www.britannica.com/science/ear/The-physiology-of-hearing

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Medial View of the Middle Ear
1. Air-filled cavity between the tympanic membrane and the cochlea
2. Contains three bones called ossicles:
a. Malleus → incus → stapes
b. Vibrations are transmitted and amplified along the bones.
c. The stapes is attached to the oval window, which transfers the vibrations
into the cochlea in the inner ear.
d. Stapedius muscle dampens the stapes if the sound is too intense

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The Cochlea
1.The cochlea is the hearing part of the inner
ear. It has a characteristic snail-shaped structure.
It is composed of three chambers:

1.The upper chamber is called the scala
vestibuli.

2.The lower chamber called the scala tympani.
Both chambers are filled with perilymph.

3.The cochlea also contains a portion of the
membranous labyrinth called the scala media, or
cochlear duct, filled with endolymph. This
chamber contains the sensitive element in the
inner ear the organ of Corti (Spiral organ).

4.Endolymph (High K+) and perilymph vary
significantly in their concentration of ions. This
difference is essential to the overall function of
the cochlea.
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The Cochlea
Journey of sound vibrations reaching
The organ of Corti

1.Vibrations from the oval window of the
middle ear displace perilymph in the scala
vestibuli.

2.Vibrations pass through the vestibular
membrane into the scala media (or
cochlear duct) through the endolymph.

3.Next, vibrations pass through the
basilar membrane into the perilymph of
the scala tympani.

4.Vibrations leave the inner ear via the
round window.

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The Cochlea: Organ of Corti

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Spiral Organ (Organ of Corti)

1. The organ of Corti is the sensitive element
in the inner ear and can be thought of as the
body's microphone
2. Sensory hair cells are located on the
basilar membrane, projecting into the
endolymph (High K+) of the cochlear duct
a. Inner hair cells: they transform
sound waves into nerve impulses.
Each is innervated by 10 to 20
sensory neurons of cranial nerve VIII
and relay sound.
b. Outer hair cells: their role is mostly to
amplify softer sound and sharpen
pitch perception by changing their
length. Such movement are believed to
aid the sensory function of the inner
hair cells

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How hearing works
a. When sound waves enter the scala media, the tectorial membrane vibrates, bending stereocilia of
the inner hair cells.

1) Opens mechanically-gated K+ channels that are facing the endolymph
2) K+ rushes in, depolarizing the cell….wait what? ionic gradients unique to the endolymph (High K+).
3) The hair cell itself does not fire an action potential. Instead, the influx of positive ions from the
endolymph in the scala media depolarizes the cell, resulting in a receptor potential.
4) Releases glutamate onto sensory neurons
5) The greater the amount of basilar membrane displacement and bending the stereocilia, the more
glutamate is released, producing a greater receptor potential.

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The Cochlea: tonotopic organization

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Neural Pathways
1. Vestibulocochlear nerve →
2. Cochlear nuclei in the medulla
oblongata & pons→
3. Inferior colliculus of midbrain →
4. Medial geniculate body of the
thalamus →
5. Auditory cortex of temporal lobe;

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Hearing Impairment
1. Conduction deafness: Sound waves are not conducted from
the outer to the inner ear.
a. May be due to a buildup of earwax, too much fluid in the middle ear,
damage to the eardrum, or overgrowth of bone in the middle ear
b. Impairs hearing of all sound frequencies
c. Can be helped by hearing aids

2. Sensorineural/perceptive deafness: Nerve impulses are not
conducted from the cochlea to the auditory cortex.
a. May be due to damaged hair cells (from loud noises)
b. May only impair hearing of particular sound frequencies and not others
c. May be helped by cochlear implants

3. Presbycusis – age-related hearing impairment

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II. Cutaneous Sensations

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Cutaneous Receptors
1.Pain, cold, and heat receptors are
naked dendrites of sensory neurons.
a. Free nerve endings
2.Touch and pressure receptors have
special structures around their
dendrites.
a. Merkel’s disks
b. Meissner’s corpuscles:
c. Pacinian corpuscles:
d. Ruffini corpuscles

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Cutaneous Receptors: temperature
Cold Receptors: Transient receptor potential (TRP) channel
a. There are many more receptors that respond to cold than to hot.
b. Located close to the epidermis
c. Stimulated by cold and inhibited by warm
d. Some cold receptors also respond to menthol
e. The temperature range of response is 8 to 28°C

Warm Receptors: Transient receptor potential (TRP) channel
a. Located deeper in the dermis
b. Excited by warming and inhibited by cooling
c. Different from receptors that detect painful heat (see below)

Hot Receptors: Transient receptor potential (TRP) channel
a. The pain experienced by a hot stimulus is sensed by a special
nociceptor called a capsaicin receptor.
b. Also a receptor for the chemical found in chili peppers (capsaicin)
c. Activated at 43°C or higher

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Pain Receptors
a. Nociceptors can be myelinated or unmyelinated.
1) Sudden, sharp pain is transmitted by myelinated neurons.
2) Dull, persistent pain is transmitted by unmyelinated neurons.
b. Nociceptors may be activated by chemicals released by damaged tissues, such as
ATP, or by pH change or mechanical stimuli.

7. Itch Sensation
a. Acute itch stimulated by histamine release from mast cells and basophils.
b. Chronic itch stimulated by other chemicals and does not respond to antihistamines
c. Receptors stimulate unmyelinated sensory axons to the spinal cord

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Neural Pathway for Somesthetic
Sensations
Tract Origin Termination Function
Anterolateral Posterior horn on one Thalamus, then Conducts pain and temperature impulses that
spinothalamic side of cord but crosses cerebral are interpreted within cerebral cortex
to opposite side cortex

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Receptive Fields and
Sensory Acuity

1. The receptive field is the area of skin that,
when stimulated, changes the firing rate of a
neuron.
a. The size of a receptive field depends on
the density of receptors in that region of
skin.
b. There are few receptors in the back and
legs, so the receptive fields are large.
c. There are many receptors in the
fingertips, so the receptive fields are
small
d. The more receptors, the smaller the
field, the larger the area of the
somatosensory cortex
e. A small receptive field = greater tactile
acuity – sharpness of the sensation

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Two-point touch threshold
a. Receptive fields can be measured by seeing at what distance a person can
perceive two separate points of touch.
b. Measures tactile acuity
c. Important in spacing the raised dots in Braille symbols

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Two-Point Touch Threshold
TABLE 10.3 The Two-Point Touch Threshold for Different
Regions of the Body

Body Region Two-Point Touch Threshold (mm)
Big toe 10
Sole of foot 22
Calf 48
Thigh 46
Back 42
Abdomen 36
Upper arm 47
Forehead 18
Palm of hand 13
Thumb 3
First finger 2
Source: Weinstein, S., and D.R. Kenshalo, editors, The Skin Senses. Springfield, Illinois:
Charles C. Thomas, Publisher, Ltd., 1968.

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VI. The Eyes and Vision

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Introduction to Vision 0

1. Vision comes from light energy transduced into nerve impulses
2. Only a limited part of the electromagnetic spectrum can excite
photoreceptors in the eye.

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Structure of the eye
1. Sclera: tough outer layer of the eyeball (the white
of the eye). The slight bulge in the sclera at the
front of the eye is the cornea. The cornea directs
light rays into the eye and helps focus them on the
retina.
2. Pupil: is the opening in the colored part of the
eye (which is called iris). It allows light to pass to
the lens.
3. Lens: normally clear and is located behind the iris.
Small muscles attached to the lens can change its
shape. This allows the eye to focus on near or far
objects.
4. Retina: thin nerve tissue that lines the back of the
eye. It detects light entering the eye and converts
it into electrical impulses.
1. Fovea-Macula: is part of the retina provides the
sharp, detailed, central vision that allows you to
focus on what is directly in the line of sight. The
rest of the retina provides side (peripheral)
vision, which allows you to see shapes but not
fine details.

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 General Pathway of light through the 1
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eye
a. Light passes through the cornea and into the anterior chamber of the eye.
b. Next, it passes through the pupil, which can change shape (due to the pigmented iris
muscle) to allow more or less light in.
c. Then it passes through the lens, which can change shape to focus the image.
d. Then passes through the posterior chamber and the vitreous body
e. Finally, it hits the retina, where photoreceptors are found.

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Structures of the Eye: Pupil and Iris
a. The iris sphincter muscle (pupillary sphincter, pupillary dilator) can increase or decrease the
diameter of the pupil.
1) Constriction: contraction of pupillary sphincter via parasympathetic stimulation
2) Dilation: contraction of pupillary dilator via sympathetic stimulation
b. The iris also has pigmented epithelium for eye color

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VII. The Retina

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Introduction to the Retina
1. The retina is approximately 0.5 mm thick and lines the back of the eye.
The retina consist of :

1. single cell pigmented epithelium,
2. photoreceptors neurons called rods and cones
3. and layer of other neurons.

2. The photosensors the rods and cone) lie outermost in the retina
against the pigment epithelium.

3. The ganglion cells (the output neurons of the retina) lie innermost
in the retina "closest" to the lens and the front of the eye.

4. The optic nerve contains the ganglion cell axons running to the brain

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Layers of the Retina: rods and cones

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Layers of the Retina: rods and cones
1. Photoreceptors (rods and cones) are
in the inner layer (toward the vitreous
body)

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Layers of the Retina: rods and cones
1. Photoreceptors (rods and cones) are
in the inner layer (toward the vitreous
body)
2. They synapse on a middle layer of
bipolar cells, which synapse on the
outer layer of ganglion cells.
3. There are also horizontal cells and
amacrine cells within the layers

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Layers of the Retina: rods and cones

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 Electrical Activity of the rods of the “On- 2
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pathway”
1. Contain the pigment rhodopsin. Rhodopsin is extremely sensitive
to light. When rhodopsin is exposed to light, it immediately
photobleaches.

Effects of Light on the Rods – “on pathway”

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 Effects of Light on the Retina – “on 2
1

pathway”
1. When Light Hits Photoreceptors
a. Dissociation of rhodopsin activates a G-
protein/2nd messenger system, which closes Na+
channels.
1) G-proteins are called transducins.
2) Activation of the enzyme
phosphodiesterase converts cGMP to
GMP.
3) This closes Na+ channels.
b. Photoreceptors are hyperpolarized, and inhibition
on bipolar cells is lifted.
c. Bipolar cells activate ganglion cells that transmit
action potentials to the brain

Inhibitory
effect

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Glutamate receptors
Receptors for glutamate fall into three major
classes, known as
1. AMPA receptors (iGluR - ligand)
2. NMDA receptors (IGluR - ligand and
voltage!)
3. Metabotropic glutamate receptors.
1. Metabotropic receptors act
through second messenger
systems to create slow, sustained
effects on their targets.

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Neural Pathway for Vision
Geniculostriate System
a. Axons from ganglion cells synapse on the lateral
geniculate nucleus of the thalamus by way of the
optic chiasma
b. Information from the lateral portion of the retinas
does not cross sides, but information from the
medial portion does.
c. Neurons from the thalamus synapse on the
visual cortex of the occipital lobe.
d. Carries information of “what” is seen

Tectal System
a. 20 to 30% of the ganglion cell axons
synapse on the superior colliculus of
the midbrain, which helps with eye and
body movements.
b. Carries information about “where” the
object is
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III. Taste and Smell

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Introduction: Taste and Smell
1. Chemoreceptors
a. Interoceptors detect chemical changes within the
body.
b. Exteroceptors detect changes from outside the
body; include taste and smell.
1) Taste responds to chemicals dissolved in food and
drink.
2) Smell responds to chemical molecules from the air.
3) Olfaction greatly influences gustation

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Taste

1. Also called gustation: Sweet;
Sour; Acid; Bitter Umami
(Savory). Receptor cells are
called “Taste cells”
2. Taste cells are specialized
epithelial cells with long
microvilli that extend out
through the pore in the taste
bud to the environment of the
mouth
3. Taste cells are organized in taste
buds – each taste bud consist
of 50 to 100 taste cells.
4. Taste buds (and the taste cells)
constantly regenerate throughout
adult life - ever~2 weeks

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Location of Taste Buds
a. Located in bumps on the tongue called papillae
b. Types of papillae:
1) Fungiform: anterior surface
a) Information travels via facial nerve.
2) Circumvallate: posterior surface
a) Information travels via glossopharyngeal nerve.
3) Foliate: sides
a) Information travels via glossopharyngeal nerve.

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Taste cells
Specialized epithelial cells

1) They behave like neurons by depolarizing (receptor potential) and releasing neurotransmitters.

2) Microvilli are equipped with receptors (T1 and T2) and encounter chemicals; the binding of the taste
chemical with the receptors lead to depolarization of the taste cell.

3) Cells release neurotransmitters (ATP and serotonin) onto sensory neurons.

4) Each taste bud has taste cells sensitive to each category of tastes.

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Taste pathways
Facial and glossopharyngeal nerves
→
Medulla oblongata (NST) →
Thalamus →
Primary gustatory cortex of insula,
somatosensory cortex of parietal
lobe, and prefrontal cortex

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Smell
1. Olfactory Apparatus
a. Smell is also called olfaction.
b. Olfactory receptors are located in the olfactory epithelium of the nasal cavity.
c. Basal stem cells replace receptors damaged by the environment.

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Smell: a mature OSN express only one OR 1

gene

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2
Smell
How Smell Works
a. G-protein coupled
b. Odor binding activates
adenylate cyclase to make
cAMP and PPi
(pyrophosphate)
c. cAMP opens Na+ and Ca2+
channels
d. Produces a graded
depolarization which
stimulates the action potential
e. Up to 50 G-proteins may be
associated with 1 receptor
protein – gives great
sensitivity through
amplification

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Smell

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Smell
b. The mitral and tufted neurons
of the glomeruli in the
olfactory bulb synapse on the
primary olfactory cortex of the
frontal and parietal lobes
c. Interconnections are made
with the amydgala,
hippocampus, and limbic
system through the piriform
cortex

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 1

III. Taste and Smell

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 2

Introduction: Taste and Smell
1. Chemoreceptors
a. Interoceptors detect chemical changes within the
body.
b. Exteroceptors detect changes from outside the
body; include taste and smell.
1) Taste responds to chemicals dissolved in food and
drink.
2) Smell responds to chemical molecules from the air.
3) Olfaction greatly influences gustation

© 2019 McGraw-Hill Education
 3

Taste

1. Also called gustation: Sweet;
Sour; Acid; Bitter Umami
(Savory). Receptor cells are
called “Taste cells”
2. Taste cells are specialized
epithelial cells with long
microvilli that extend out
through the pore in the taste
bud to the environment of the
mouth
3. Taste cells are organized in taste
buds – each taste bud consist
of 50 to 100 taste cells.
4. Taste buds (and the taste cells)
constantly regenerate throughout
adult life - ever~2 weeks

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 4

Location of Taste Buds
a. Located in bumps on the tongue called papillae
b. Types of papillae:
1) Fungiform: anterior surface
a) Information travels via facial nerve.
2) Circumvallate: posterior surface
a) Information travels via glossopharyngeal nerve.
3) Foliate: sides
a) Information travels via glossopharyngeal nerve.

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 5

Taste cells
Specialized epithelial cells

1) They behave like neurons by depolarizing (receptor potential) and releasing neurotransmitters.

2) Microvilli are equipped with receptors (T1 and T2) and encounter chemicals; the binding of the taste
chemical with the receptors lead to depolarization of the taste cell.

3) Cells release neurotransmitters (ATP and serotonin) onto sensory neurons.

4) Each taste bud has taste cells sensitive to each category of tastes.

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 6

Taste pathways
Facial and glossopharyngeal nerves
→
Medulla oblongata (NST) →
Thalamus →
Primary gustatory cortex of insula,
somatosensory cortex of parietal
lobe, and prefrontal cortex

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 7

Smell
1. Olfactory Apparatus
a. Smell is also called olfaction.
b. Olfactory receptors are located in the olfactory epithelium of the nasal cavity.
c. Basal stem cells replace receptors damaged by the environment.

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 8
Smell: a mature OSN express only one OR
gene

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 9

Smell
How Smell Works
a. G-protein coupled
b. Odor binding activates
adenylate cyclase to make
cAMP and PPi
(pyrophosphate)
c. cAMP opens Na+ and Ca2+
channels
d. Produces a graded
depolarization which
stimulates the action potential
e. Up to 50 G-proteins may be
associated with 1 receptor
protein – gives great
sensitivity through
amplification

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0
Smell

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 1
1
Smell
b. The mitral and tufted neurons
of the glomeruli in the
olfactory bulb synapse on the
primary olfactory cortex of the
frontal and parietal lobes
c. Interconnections are made
with the amydgala,
hippocampus, and limbic
system through the piriform
cortex

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Nervous system vs. endocrine system

Electrical impulses are Information is
the mode in which transmitted via the
information is blood vessels.
transmitted. Hormones are the
Neurotransmitters are messenger in the
the messenger in the endocrine system.
nervous system.

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Common Aspects of Neural and Endocrine Regulation

1. Hormones and neurotransmitters both interact with
specific receptors.
2. Binding to a receptor causes a change within the cell.
3. There are mechanisms to turn off target cell activity; the
signal is either removed or inactivated.
4. Some hormones can also be neurotransmitters in the CNS
1. Noradrenaline (Norepinephrine)
2. Adrenaline (Epinephrine)

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Hormone Interactions
1. A target tissue is usually responsive to several
different hormones.
a. Hormones may be
a. Synergistic
i. Complementary
ii. Addictive
b. Antagonistic
c. Permissive

b. How a cell responds depends on the amount of
hormone and the combination of all hormones.
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 Hormone Interactions: Synergistic 1
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Effects
a. Occur when two or more hormones work together to produce
a particular effect
b. Effects may be additive, as when epinephrine and
norepinephrine each affect the heart in the same way.
c. Effects may be complementary, as when each hormone
contributes a different piece of an overall outcome.
1) For example, lactation requires estrogen, prolactin, and
oxytocin

1) Estrogen and progesterone prepare the breasts to make milk.
2) Prolactin helps the breasts make milk.
3) Oxytocin releases milk from the breasts.

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 Hormone Interactions: Antagonistic 1
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Effects
a. Occur when hormones work in opposite directions.
b. Insulin and glucagon affect both glucose blood-
levels and adipose tissue.
1) Insulin stimulates cellular uptake of glucose and promote fat
storage by inhibition of fat breakdown.
2) Glucagon stimulates glucose production (gluconeogenesis) and
secretion in the blood, and stimulate fat breakdown (Lipolysis,
ketogenesis).

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 Hormone Interactions: Permissive 1
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Effects
a. Occur when one hormone makes the target cell more responsive to a second
hormone
1) Exposure to estradiol makes the uterus more responsive to progesterone.

2) Increased secretion of parathyroid (PTH) hormone makes the intestines more
responsive to Vit D3 in calcium absorption

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Effects of Hormone Concentrations on Tissue Response

1. Hormone Half-life
a. The time required for the plasma concentration of a given amount of
hormone to be reduced by half
b. The half-life of hormones circulating in the blood ranges from minutes to
hours to days.
c. Most hormones are removed from the blood by the liver and converted
to less active products

2. Hormone Concentration
a. Tissues only respond when hormone concentrations are at a certain
“normal” or physiological level.
b. At higher pharmacological concentrations (when taken as drugs), effects may
be different from normal.
1) High concentrations may result in binding to receptors of different (but
closely related) hormones.
2) This can result in widespread side effects.

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Effects of Hormone Concentrations on Tissue Response

3. Priming Effects/Up-regulation
a. Some target cells respond to a particular hormone by
increasing the number of receptors it has for that hormone.
b. This makes it more sensitive to subsequent hormone
release and have a greater response

4. Desensitization and Downregulation
a. Prolonged exposure to high concentrations of hormone may
result in a decreased number of receptors for that hormone.
b. To avoid desensitization, many hormones are released in
spurts, called pulsatile secretion.

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II. Mechanisms of Hormone Action

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Introduction: Hormone Action
1. Hormones bind to receptors on or
in target cells.
a. Binding is highly specific
(high affinity).
b. Hormones bind to receptors
with a low capacity;
saturating the receptors with
hormone molecules

2. Lipophilic hormone receptors
are in the cytoplasm or nucleus

3. Water-soluble hormone
receptors are on the outer
surface of the plasma
membrane

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Hormones That Bind to Nuclear Receptor Proteins

Lipophilic steroid hormones and thyroid
hormones:
a. Travel (in the bloodstream) to target cells
attached to carrier proteins
b. At the target cell, dissociate from the carrier
protein and diffuse across the plasma
membrane
c. Receptors are found within the nucleus or the
cytoplasm and are called nuclear hormone
receptors because they activate genetic
transcription
These hormone receptors serve as transcription
factors (genomic action).
a. They are activated by the binding of the
hormone
b. The effect of these hormones is therefore to
produce new proteins, usually enzymes
that change metabolism inside the cell.
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Hormones That Bind to Nuclear Receptor Proteins

a. Two regions on the receptor:
1) Ligand-binding domain for the
hormone
2) DNA-binding domain for DNA

b. Binding of the hormone activates the
DNA- binding domain, that binds to a
hormone response element on the
DNA

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Introduction: Hormone Action
1. Hormones bind to receptors on or
in target cells.
a. Binding is highly specific
(high affinity).
b. Hormones bind to receptors
with a low capacity;
saturating the receptors with
hormone molecules

2. Lipophilic hormone receptors
are in the cytoplasm or nucleus

3. Water-soluble hormone
receptors are on the outer
surface of the plasma
membrane

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Water soluble hormones Use 2nd Messengers 5

1. These hormones cannot cross the plasma membrane, so they bind to
receptors on the cell surface.
2. Activate an intracellular mediator called a second messenger
3. There are three possible 2nd messenger mechanisms:
a. Adenylate cyclase
b. Phospholipase C
c. Tyrosine kinase

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Adenylate Cyclase (cAMP) System

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Phospholipase C System

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Tyrosine Kinase System

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Endocrine system 9

The endocrine system is composed
of a network of endocrine glands

Hypothalamus (in part)
Pituitary gland
Pineal gland
Thyroid
Parathyroid
Thymus
Adrenal
Pancreas
Ovaries
Testes
Placenta

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Hypothalamus and pituitary gland

The pituitary gland is often referred to as the "master gland" of the body.

The hypothalamus decides which hormones the pituitary should
release…how?.... by sending either hormonal or electrical messages.

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 Hypothalamus and posterior Pituitary 3
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Gland
The posterior pituitary (neurohypophysis) is
an extension of the neurons of the
paraventricular and supraoptic nuclei of the
hypothalamus.

The cell bodies of these regions rest in the
hypothalamus, but their axons descend as the
hypothalamic–hypophyseal tract and end in
axon terminals that comprise the posterior
pituitary

The posterior pituitary gland does not produce
hormones, but rather stores and secretes
hormones produced by the hypothalamus.

The paraventricular nuclei produce the
hormone oxytocin, whereas the supraoptic
nuclei produce ADH. These hormones travel
along the axons and are stored the axon
terminals of the posterior pituitary.

In response to signals from the same Antidiuretic hormone (ADH) Peptide Stimulates water reabsorption by kidneys

hypothalamic neurons, the hormones are
released from the axon terminals into the Stimulates uterine contractions during
bloodstream. Oxytocin Peptide
childbirth

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 Hypothalamus and anterior Pituitary 3
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Gland
The anterior pituitary does manufacture hormones.
However, the production and secretion of
hormones from the anterior pituitary is regulated
by hormones released by the hypothalamus.

Hypothalamic hormones are secreted by neurons, but
enter the anterior pituitary through the hypophyseal
portal system (primary capillary plexus; they don’t
enter the systemic circulation at this point!)
The hypothalamus can release the following hormones.
Hormones produced by the anterior pituitary (in
Thyrotropin-releasing hormone (TRH)
response to releasing hypothalamic hormones) enter a
Corticotropin-releasing hormone (CRH)
secondary capillary plexus, and from there drain into
Somatostatin
the circulation.
Gonadotropin-releasing hormone (GnRH)
The anterior pituitary produces seven hormones.
growth hormone (GH), Growth hormone (GH) Promotes growth of body tissues
thyroid-stimulating hormone (TSH)
adrenocorticotropic hormone (ACTH), Prolactin (PRL) Promotes milk production from mammary glands

follicle-stimulating hormone (FSH),
TSH Stimulates thyroid hormone release from thyroid
luteinizing hormone (LH),
beta endorphin, and prolactin (not in the graph). ACTH Stimulates hormone release by adrenal cortex